Multifocal lens having reduced chromatic aberrations

ABSTRACT

A method and system provide a multifocal ophthalmic device. The ophthalmic lens has an anterior surface, a posterior surface and at least one diffractive structure including a plurality of echelettes. The echelettes have at least one step height of at least one wavelength and not more than two wavelengths in optical path length. The diffractive structure(s) reside on at least one of the anterior surface and the posterior surface. The diffractive structure(s) provide a plurality of focal lengths for the ophthalmic lens.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a continuation of U.S. patent application Ser. No.16/541,422 filed Aug. 15, 2019, which is a continuation of Ser. No.15/363,398 filed Nov. 29, 2016, by Myoung-Taek Choi, et al., andentitled “Multifocal Lens Having Reduced Chromatic Aberrations,” whichis incorporated herein by reference.

FIELD

The present disclosure relates generally to ophthalmic lenses and moreparticularly to multifocal ophthalmic lenses having reduced chromaticaberrations.

BACKGROUND

Intraocular lenses (IOLs) are implanted in patients' eyes either toreplace a patient's lens or to complement the patient's lens. The IOLmay be implanted in place of the patient's lens during cataract surgery.Alternatively, an IOL may be implanted in a patient's eye to augment theoptical power of the patient's own lens.

Some conventional IOLs are single focal length IOLs, while others aremultifocal IOLs. Single focal length IOLs have a single focal length orsingle power. Objects at the focal length from the eye/IOL are in focus,while objects nearer or further away may be out of focus. Althoughobjects are in perfect focus only at the focal length, objects withinthe depth of field (within a particular distance of the focal length)are still acceptably in focus for the patient to consider the objects infocus. Multifocal IOLs, on the other hand, have at least two focallengths. For example, a bifocal IOL has two focal lengths for improvingfocus in two ranges: a far focus corresponding to a larger focal lengthand a near focus corresponding to a smaller focal length. Thus, apatient's distance vision and near vision may be improved. Aconventional diffractive bifocal IOL typically uses the 0^(th)diffractive order for distance focus/vision and the 1^(st) diffractionorder for near focus/vision. Trifocal IOLs have three foci: a far focusfor distance vision, a near focus for near vision and an intermediatefocus for intermediate vision that has an intermediate focal lengthbetween that of the near and far focuses. A conventional diffractivetrifocal IOL typically uses the 0^(th) diffractive order for distancevision, the 1^(st) diffractive order for intermediate vision and the2^(nd) diffraction order for near vision. Multifocal IOLs may improvethe patient's ability to focus on distant and nearby objects. Stateddifferently, the depth of focus for the patient may be enhanced.

Although multifocal lenses may be used to address conditions such aspresbyopia, there are drawbacks. Multifocal IOLs may also suffer fromlongitudinal chromatic aberration. Different colors of light havedifferent wavelengths and, therefore, different foci. As a result, themultifocal IOL focuses light of different colors at different distancesfrom the lens. The multifocal IOL may be unable to focus light ofdifferent colors at the patient's retina. The polychromatic imagecontrast for the multifocal IOL, particularly for distance vision, maybe adversely affected.

Accordingly, what is needed is a system and method for addressingchromatic aberration in multifocal IOLs.

SUMMARY

A method and system provide a multifocal ophthalmic device. Theophthalmic lens has an anterior surface, a posterior surface and atleast one diffractive structure including a plurality of echelettes. Theechelettes have at least one step height of at least one wavelength andnot more than two wavelengths in optical path length. The diffractivestructure(s) reside on at least one of the anterior surface and theposterior surface. The diffractive structure(s) provide a plurality offocal lengths for the ophthalmic lens.

The multifocal lens may have the diffractive structure(s) describedabove may have reduced chromatic aberration. As a result, image qualitymay be improved.

BRIEF DESCRIPTION OF THE DRAWINGS

For a more complete understanding of the present disclosure and theadvantages thereof, reference is now made to the following descriptiontaken in conjunction with the accompanying drawings in which likereference numerals indicate like features and wherein:

FIGS. 1A and 1B depict a plan and side views of an exemplary embodimentof a multifocal ophthalmic device that may have reduced chromaticaberration;

FIG. 2 depicts a side view of an exemplary embodiment of a diffractivestructure for a bifocal lens of an ophthalmic device that may havereduced chromatic aberration;

FIGS. 3A-3B depict exemplary embodiments of the intensity versusdistance for a bifocal lens that may have reduced chromatic aberrationand for a lens made without accounting for chromatic aberrationreduction;

FIG. 4 depicts a side view of an exemplary embodiment of a diffractivestructure for a trifocal lens of an ophthalmic device that may havereduced chromatic aberration;

FIGS. 5A-5B depict exemplary embodiments of the intensity versusdistance for a trifocal lens that may have reduced chromatic aberrationand for a lens made without accounting for chromatic aberrationreduction;

FIG. 6 depicts a side view of an exemplary embodiment of a diffractivestructure for a quadrifocal lens of an ophthalmic device that may havereduced chromatic aberration;

FIGS. 7A-7B depict exemplary embodiments of the intensity versusdistance for a quadrifocal lens that may have reduced chromaticaberration and for a lens made without accounting for chromaticaberration reduction;

FIG. 8 depicts a side view of another exemplary embodiment of amultifocal diffractive lens of an ophthalmic device that may havereduced chromatic aberration;

FIG. 9 is flow chart depicting an exemplary embodiment of a method forfabricating an ophthalmic device that may have reduced chromaticaberration; and

FIG. 10 is flow chart depicting an exemplary embodiment of a method forutilizing an ophthalmic device including a multifocal lens that may havereduced chromatic aberration.

DETAILED DESCRIPTION

The exemplary embodiments relate to ophthalmic devices such as IOLs andcontact lenses. The following description is presented to enable one ofordinary skill in the art to make and use the invention and is providedin the context of a patent application and its requirements. Variousmodifications to the exemplary embodiments and the generic principlesand features described herein will be readily apparent. The exemplaryembodiments are mainly described in terms of particular methods andsystems provided in particular implementations. However, the methods andsystems will operate effectively in other implementations. For example,the method and system are described primarily in terms of IOLs. However,the method and system may be used with contact lenses and spectaclelenses. Phrases such as “exemplary embodiment”, “one embodiment” and“another embodiment” may refer to the same or different embodiments aswell as to multiple embodiments. The embodiments will be described withrespect to systems and/or devices having certain components. However,the systems and/or devices may include more or less components thanthose shown, and variations in the arrangement and type of thecomponents may be made without departing from the scope of theinvention. The exemplary embodiments will also be described in thecontext of particular methods having certain steps. However, the methodand system operate effectively for other methods having different and/oradditional steps and steps in different orders that are not inconsistentwith the exemplary embodiments. Thus, the present invention is notintended to be limited to the embodiments shown, but is to be accordedthe widest scope consistent with the principles and features describedherein.

A method and system provide a multifocal ophthalmic device. Theophthalmic device includes an ophthalmic lens configured for use basedupon a wavelength. The ophthalmic lens has an anterior surface, aposterior surface and at least one diffractive structure including aplurality of echelettes. The echelettes have at least one step height ofat least one wavelength and not more than two wavelengths in opticalpath length. The diffractive structure(s) reside on at least one of theanterior surface and the posterior surface. The diffractive structure(s)provide a plurality of focal lengths for the ophthalmic lens.

FIGS. 1A-1B depict an exemplary embodiment of an ophthalmic device 100that may be used as an IOL. FIG. 1A depicts a plan view of theophthalmic device 100, while FIG. 1B depicts a side view of theophthalmic lens 110. For clarity, FIGS. 1A and 1B are not to scale andonly some features are shown. The ophthalmic device 100 includes anophthalmic lens 110 (herein after “lens”) as well as haptics 102 and104. The lens 110 may be made of a variety of optical materialsincluding but not limited to one or more of silicone, a hydrogel, anacrylic and AcrySof®. Haptics 102 and 104 are used to hold theophthalmic device 100 in place in a patient's eye (not explicitlyshown). However, in other embodiments, other mechanism(s) might be usedto retain the ophthalmic device in position in the eye. Thus, thehaptics 102 and/or 104 might be omitted. For clarity, the haptics arenot depicted in the remaining drawings. Although the lens 110 isdepicted as having a circular cross section in the plan view of FIG. 1 ,in other embodiments, other shapes may be used. Further, althoughdescribed in the context of an IOL, the lens 110 may be a contact lens.In such a case, the haptics 102 would be omitted and the lens 110 sizedand otherwise configured to reside on the surface of the eye.

The lens 110 is a multifocal lens. The lens 110 has an anterior surface112 a posterior surface 114 and an optic axis 116. The lens is alsocharacterized by a diffractive structure 120 and a base curvature 124.The lens 110 may be determined provide a base power, astigmatismcorrection and/or other vision correction(s). The lens 110 may beaspheric, toroidal and/or biconic, have the same or different basecurvatures on the surfaces 112 and 114 and/or other characteristics thatare not shown or discussed in detail for simplicity. Although onediffractive structure 120 is shown on the anterior surface 112, thediffractive structure 120 might be located on the posterior surface 114.In still other embodiments, diffractive structures may be located on theanterior surface 112 and the posterior surface 114. Such diffractivestructures may be the same or different. The diffractive structure 120may, but need not, be partial aperture diffractive structure. In suchembodiments, a refractive power compensator may be incorporated into thebase curvature 124 in the diffractive zone to neutralize the basediffractive power.

The lens 110 may have zones 111 corresponding to different ranges indistance perpendicular to the optic axis 116 (i.e. different radii). Azone 111 is a circle or an annular ring along the surface from a minimumradius to a maximum radius from the optic axis 116. The diffractivestructure 120 and/or the base curvature 124 may be different indifferent zones. For example, in some embodiments, the diffractivestructure 120 may have ring diameters for the zones set by the Fresneldiffractive lens criteria. Alternatively, other criteria may be used. Inother embodiments, one or both of these features may not change betweenzones. For example, the base curvature may be consistent across theanterior surface 112, while the diffractive structure 120 changes fordifferent zones 111. The diffractive structure 120 may use differentdiffractive orders to create multiple focuses, as described below.

The diffractive structure 120 provides multiple focal lengths. In someembodiments, for example, the diffractive structure 120 is used toprovide a bifocal (two focal lengths for near and distance vision) lens110. In other embodiments, the diffractive structure 120 may provide atrifocal (three focal lengths for near, intermediate and distancevision) lens 110. A quadrifocal or other multifocal lens might also beprovided. The diffractive structure 120 is configured for particularwavelength(s). For example, different zones 111 of the diffractivestructure 120 may be configured for light of different wavelengths.Alternatively, the diffractive structure 120 may be designed for lightof a single wavelength. Without more, such a structure would suffer fromchromatic aberration.

The diffractive structure 120 includes and is formed of steps termedechelettes 122. As can be seen in FIG. 1B, the physical height of theechelettes 122 may vary. In other embodiments, the physical height ofthe echelettes 122 may be constant. The spacing between the echelettes122 and other characteristics of the echelettes 122 may also stay thesame or vary across the lens 110. The optical step height of theechelettes 122 is the physical height (shown in FIG. 1B) multiplied bythe difference between the index of refraction of the lens 110 and theindex of refraction of the surrounding media in which the lens 110 is tobe used.

The optical step height(s) of the echelettes 122 may be not less thanthe wavelength of light and not more than twice the wavelength of light.In other words, λ≤Δn·h≤2λ, where h is the physical height of theechelette 122, λ is the wavelength of light for which the appropriateregion of the diffractive structure 120 is configured and Δn is thedifference in the index of refraction described above. In someembodiments, λ<Δn·h<2λ. The echelettes 122 may also be apodized (have adecreased step height). However, the minimum step height for suchapodized echelettes 122 is still λ. Utilizing a step height in thisrange excludes the zeroth (0^(th)) diffractive order from use in thelens 110.

In some embodiments, for example, the diffractive structure 120 is usedto provide a bifocal (two focal lengths for near and distance vision)lens 110. A bifocal lens 110 may utilize the first (1^(st)) diffractiveorder and the second (2^(nd)) diffractive order. In some embodiments,the 1^(st) diffractive order is utilized for distance vision, while the2^(nd) diffractive order is used for near vision. In other embodiments,the diffractive structure 120 may provide a trifocal (three focallengths for near, intermediate and distance vision) lens 110. A trifocallens 110 may utilize the 1^(st) diffractive order, the 2^(nd)diffractive order and the third (3rd) diffractive order. In someembodiments, the 1^(st) diffractive order is used for distance vision,the 2^(nd) diffractive order is used for intermediate vision and the3^(rd) diffractive order is used for near vision. In other embodiments,the diffractive structure 120 is configured for a quadrifocal lens 110.Such a quadrifocal lens 110 may utilize the 1^(st) diffractive order,the 2^(nd) diffractive order, the 3^(rd) diffractive order and thefourth (4^(th)) diffractive order. In some embodiments, the 1^(st)diffractive order is used for distance vision, the 2^(nd) diffractiveorder may be empty, the 3^(rd) diffractive order is used forintermediate vision and the 4^(th) diffractive order is used for nearvision. In other embodiments, the 1^(st) diffractive order is used fordistance vision, the 2^(nd) diffractive order may be used forintermediate vision, the 3rd diffractive order may be empty and the4^(th) diffractive order is used for near vision. In other embodiments,different diffractive orders may be used for different focal ranges.However, the 0^(th) order is excluded.

The lens 110 may have improved performance while maintaining thebenefits of a multifocal lens. Because the lens 110 is a multifocallens, the ophthalmic device 100 may be used to treat conditions such aspresbyopia. Other conditions may be treated and performance of the lens110 may be improved through the use of the base curvature 124,asphericity of the lens 110, toricity of the lens 110, apodization ofthe echelettes 122 and other characteristics of the lens. In addition,the lens 110 may have reduced chromatic aberration. Configuration of theechelettes 122 to exclude the 0^(th) diffractive order (e.g. have a stepheight that is at least equal to the wavelength and not more than twicethe wavelength of light) may reduce the longitudinal chromaticaberration. In some embodiments, the chromatic aberration may besignificantly reduced. Consequently, polychromatic or white light imagecontrast may be improved for distance, near, and/or intermediate visionfor multifocal lenses 110. Performance of the lens 110 and ophthalmicdevice 100 may thus be enhanced.

The benefits of the ophthalmic lens 110 may be better understood withrespect specific bifocal, trifocal and quadrifocal embodiments. FIG. 2depicts a side view of another exemplary embodiment of a diffractivestructure 130 that may be used in a bifocal diffractive lens 110. FIGS.3A and 3B are graphs 140 and 150, respectively, depicting exemplaryembodiments of the intensity versus distance for a reduced chromaticaberration bifocal lens 110 made with the diffractive structure 130 andfor a bifocal diffractive lens made without accounting for chromaticaberration reduction. Referring to FIGS. 2-3B, the diffractive structure130 may take the place of the diffractive structure 120. The diffractivestructure 130 is shown with the base curvature removed. FIGS. 2-3B arenot to scale and for explanatory purposes only.

The diffractive structure 130 has echelettes 132 having a singlephysical height, h. This physical height corresponds to a single stepheight for the lens 110. As indicated in FIG. 2 , the step height is notless than the wavelength for which the diffractive structure 130 isconfigured and not more than twice the wavelength for which thediffractive structure 130 is configured (λ≤Δn·h≤2λ). In someembodiments, λ<Δn·h<2λ. The diffractive structure 130 thus omits the0^(th) order.

FIG. 3A is a graph 140 depicting the intensity versus distance for twowavelengths for a bifocal lens using the diffractive structure 130. Theintensity versus distance for green light is shown by dashed curve 142,while the intensity versus distance for polychromatic light is shown bycurve 144. FIG. 3B is a graph 150 depicting the intensity versusdistance for two wavelengths for a bifocal lens that does not accountfor chromatic aberration reduction. The intensity versus distance forgreen light is shown by dashed curve 152, while the intensity versusdistance for polychromatic light is shown by curve 154. As can be seenby a comparison between graphs 140 and 150, the peaks for the curves 142and 144 match significantly more closely than the peaks for the curves152 and 154. The diffractive structure 130 focuses light havingdifferent wavelengths at distances that are closer to being the same.Thus, chromatic aberration has been reduced for the diffractivestructure 130.

FIG. 4 depicts a side view of another exemplary embodiment of adiffractive structure 130′ that may be used in a trifocal diffractivelens 110. FIGS. 5A and 5B are graphs 140′ and 150′, respectively,depicting exemplary embodiments of the intensity versus distance for areduced chromatic aberration trifocal lens 110 made with the diffractivestructure 130′ and for a trifocal diffractive lens made withoutaccounting for chromatic aberration reduction. The diffractive structure130′ thus omits the 0^(th) order. Referring to FIGS. 4-5B, thediffractive structure 130′ may take the place of the diffractivestructure 120. The diffractive structure 130′ is shown with the basecurvature removed. FIGS. 4-5B are not to scale and for explanatorypurposes only.

The diffractive structure 130′ has echelettes 132′ having a twodifferent physical heights, h1 and h2. These physical heights correspondto two step heights for the lens 110 (h1≠h2). As indicated in FIG. 4 ,the step heights are not less than the wavelength for which thediffractive structure 130′ is configured and not more than twice thewavelength for which the diffractive structure 130 is configured(λ≤Δn·h1≤2λ and λ≤Δn·h2≤2λ). In some embodiments, λ<Δn·h1<2λ andλ<Δn·h2<2λ. The diffractive structure 130′ thus omits the 0^(th) order.

FIG. 5A is a graph 140′ depicting the intensity versus distance forgreen light in dashed curve 142′ and polychromatic light in curve 144′for a trifocal lens using the diffractive structure 130′. FIG. 3B is agraph 150′ depicting the intensity versus distance for green light indashed 152′ and polychromatic light in curve 154′ for a trifocal lensthat does not account for chromatic aberration reduction. As can be seenby a comparison between graphs 140′ and 150′, the peaks for the curves142′ and 144′ match significantly better than the peaks for the curves152′ and 154′. Light having different wavelengths are thus focused atdistances that are closer to being the same. Thus, chromatic aberrationhas been reduced for the diffractive structure 130′.

FIG. 6 depicts a side view of another exemplary embodiment of adiffractive structure 130″ that may be used in a quadrifocal diffractivelens 110. FIGS. 7A and 7B are graphs 140″ and 150″, respectively,depicting exemplary embodiments of the intensity versus distance for areduced chromatic aberration quadrifocal lens 110 made with thediffractive structure 130″ and for a quadrifocal diffractive lens madewithout accounting for chromatic aberration reduction. Referring toFIGS. 6-7B, the diffractive structure 130″ may take the place of thediffractive structure 120. The diffractive structure 130″ is shown withthe base curvature removed. FIGS. 6-7B are not to scale and forexplanatory purposes only.

The diffractive structure 130″ has echelettes 132″ having a threedifferent physical heights, h1′, h2′ and h3. These physical heightscorrespond to three different step heights for the lens 110 (h1′≠h2′,h1′≠h3, h2′≠h3). As indicated in FIG. 6 , the step heights are not lessthan the wavelength for which the diffractive structure 130″ isconfigured and not more than twice the wavelength for which thediffractive structure 130 is configured (λ≤Δn·h1′≤2λ, λ≤Δn·h2′≤2λ andλ≤Δn·h3≤2λ). In some embodiments, λ<Δn·h1′<2λ, λ<Δn·h2′<2λ andλ<Δn·h3<2λ. The diffractive structure 130″ thus omits the 0^(th) order.

FIG. 7A is a graph 140″ depicting the intensity versus distance forgreen light in dashed 142″ and polychromatic light in curve 144″ for aquadrifocal lens using the diffractive structure 130″. FIG. 7B is agraph 150″ depicting the intensity versus distance for green light indashed curve 152″ and polychromatic light in curve 154″ for aquadrifocal lens that does not account for chromatic aberrationreduction. As can be seen by a comparison between graphs 140″ and 150″,the peaks for the curves 142″ and 144″ match more closely than the peaksfor the curves 152″ and 154″. The diffractive structure 130″ thusfocuses light having different wavelengths at distances that are closerto being the same. Thus, chromatic aberration has been reduced for thediffractive structure 130″.

A bifocal, trifocal and/or quadrifocal lens using the diffractivestructures 130, 130′ and/or 130″ may have improved performance. Such alens may have multiple focal lengths as well as other characteristicsthat can improve treatment of the patient's vision and reduce visualartifact. In addition, configuration of the echelettes 132, 132′ and/or132″ to exclude the 0^(th) diffractive order (e.g. have a step heightthat is at least equal to the wavelength and not more than twice thewavelength of light) may reduce the longitudinal chromatic aberration.In some embodiments, the chromatic aberration may be significantlyreduced. Consequently, polychromatic or white light image contrast maybe improved for distance, near, and/or intermediate vision for thediffractive structures 130, 130′ and/or 130″. Performance of a lens andophthalmic device made using the diffractive structures 130, 130′ and/or130″ may thus be enhanced.

FIG. 8 depicts a side view of a portion of another exemplary embodimentof a lens 170 that may have reduced chromatic aberration. FIG. 8 is notto scale and for explanatory purposes only. The lens 170 has adiffractive structure 172 that is a partial aperture diffractivestructure. In such embodiments, a refractive power compensator may beincorporated into the base curvature in the diffractive zone toneutralize the base diffractive power. The diffractive structure 172 hasechelettes having a single different physical height. In otherembodiments, multiple physical heights may be used. The physicalheight(s) correspond to step height(s) for the lens. The step heightsare not less than the wavelength for which the diffractive structure 170is configured and not more than twice the wavelength for which thediffractive structure 170 is configured. The partial aperturediffractive structure 170 thus omits the 0^(th) order. Thus, the lens170 may have improved performance as described above.

FIG. 9 is an exemplary embodiment of a method 200 for providing amultifocal diffractive lens having reduced chromatic aberration. Forsimplicity, some steps may be omitted, interleaved, and/or combined. Themethod 200 is also described in the context the ophthalmic device 100and lens 110 and diffractive structure 120. However, the method 200 maybe used with one or more other diffractive structure 130′ and/or 130″and/or an analogous ophthalmic device.

The diffractive structure for the lens 110 and that does not account forchromatic aberration reduction is designed, via step 202. Step 202 mayinclude defining the zone size and characteristics, the initial stepheight(s) of the echelettes and other features of the diffractivestructure. This generally results in a diffractive structure that has astep height that is less than the wavelength.

A particular amount is added to the step height for each of theechelettes, via step 204. Step 204 generally includes adding awavelength to each step height. Regardless of the amount added, theresultant, final step height is at least one wavelength and not morethan two wavelengths. Alternatively, step 204 may include anothermechanism for removing the zeroth diffractive order from the diffractivestructure. Thus, the step height for the diffractive structure 120 isdetermined.

The lens(es) 110 are fabricated, via step 206. Thus, the desireddiffractive structure 120 having a step height that is at least as largeas the wavelength and not more than twice the wavelength may beprovided. The diffractive structure(s) 130, 130′, 130″ and/or ananalogous diffractive structure may be provided and the benefits thereofachieved.

FIG. 10 is an exemplary embodiment of a method 210 for treating anophthalmic condition in a patient. For simplicity, some steps may beomitted, interleaved, and/or combined. The method 210 is also describedin the context of using the ophthalmic device 100 and ophthalmic lens110. However, the method 210 may be used with one or more of diffractivestructures 130, 130′, 130″ and/or an analogous diffractive structure.

An ophthalmic device 100 for implantation in an eye of the patient isselected, via step 212. The ophthalmic device 100 includes an ophthalmiclens 110 having a diffractive structure 120 that has reduced chromaticaberration. A lens having a diffractive structure 120, 130, 130′, 130″and/or an analogous diffractive structure may thus be selected for use.

The ophthalmic device 100 is implanted in the patient's eye, via step204. Step 204 may include replacing the patient's own lens with theophthalmic device 100 or augmenting the patient's lens with theophthalmic device. Treatment of the patient may then be completed. Insome embodiments implantation in the patient's other eye of anotheranalogous ophthalmic device may be carried out.

Using the method 200, the diffractive structure 120, 130, 130′, 130″and/or analogous diffractive structure may be used. Thus, the benefitsof one or more of the ophthalmic lenses 110, 110′, 110″, and/or 110′″may be achieved.

A method and system for providing an ophthalmic device have beendescribed. The method and systems have been described in accordance withthe exemplary embodiments shown, and one of ordinary skill in the artwill readily recognize that there could be variations to theembodiments, and any variations would be within the spirit and scope ofthe method and system. Accordingly, many modifications may be made byone of ordinary skill in the art without departing from the spirit andscope of the appended claims.

We claim:
 1. A multifocal ophthalmic lens comprising: an anteriorsurface; a posterior surface; and a single diffractive structurecomprising a plurality of echelettes having a single physical height,the plurality of echelettes having a step height of at least onewavelength and not more than two wavelengths in optical path length, thediffractive structure residing on at least one of the anterior surfaceand the posterior surface, the diffractive structure providing: a firstdiffractive order for a first focus corresponding to a first focallength; and a second diffractive order for a second focus correspondingto a second focal length, the second focal length being different fromthe first focal length; wherein the diffractive structure excludes a 0thdiffractive order.
 2. The multifocal ophthalmic lens of claim 1, whereina chromatic aberration is reduced such that a polychromatic performanceis substantially equivalent to a principle monochromatic performance. 3.The multifocal ophthalmic lens of claim 1, wherein the lens has at leastone base curvature.
 4. The multifocal ophthalmic lens of claim 1,wherein the diffractive structure is incorporated into the anteriorsurface.
 5. The multifocal ophthalmic lens of claim 1, wherein thediffractive structure is incorporated into the posterior surface.
 6. Themultifocal ophthalmic lens of claim 1, formed by at least one of thefollowing materials: silicone, hydrogel, and acrylic.
 7. The multifocalophthalmic lens of claim 1, having a circular cross-section.
 8. Themultifocal ophthalmic lens of claim 1, having an aspheric, toroidal,and/or biconic shape.
 9. The multifocal ophthalmic lens of claim 1,wherein the ophthalmic lens is selected from an intraocular lens, acontact lens and a spectacle lens.
 10. A multifocal ophthalmic devicecomprising: an ophthalmic lens having an anterior surface, a posteriorsurface, and a plurality of echelettes having a single physical heightand included in a single diffractive structure, the plurality ofechelettes having a step height of at least one wavelength and not morethan two wavelengths in optical path length, the diffractive structureresiding on at least one of the anterior surface and the posteriorsurface, the diffractive structure providing: a first diffractive orderfor a first focus corresponding to a first focal length, and a seconddiffractive order for a second focus corresponding to a second focallength, the second focal length being different from the first focallength; wherein the diffractive structure excludes a 0th diffractiveorder; and a plurality of haptics coupled with the ophthalmic lens. 11.The multifocal ophthalmic device of claim 10, wherein the diffractivestructure is incorporated into the anterior surface.
 12. The multifocalophthalmic device of claim 10, wherein the diffractive structure isincorporated into the posterior surface.
 13. A method for fabricating amultifocal ophthalmic lens comprising: designing an ophthalmic lensconfigured for use based upon a wavelength, the ophthalmic lens havingan anterior surface, a posterior surface, and a plurality of echeletteshaving a single physical height and included in a single diffractivestructure, the plurality of echelettes having at least one initial stepheight, the diffractive structure residing on at least one of theanterior surface and the posterior surface, the diffractive structureproviding: a first diffractive order for a first focus corresponding toa first focal length; and a second diffractive order for a second focuscorresponding to a second focal length, the second focal length beingdifferent from the first focal length; wherein the diffractive structureexcludes a 0th diffractive order; adding one wavelength to the at leastone initial step height to provide at least one final step height; andfabricating the ophthalmic lens using the at least one final step heightfor the diffractive structure.
 14. The method of claim 13, wherein thediffractive structure is incorporated into the anterior surface.
 15. Themethod of claim 13, wherein the diffractive structure is incorporatedinto the posterior surface.